Mechanism for preventing ESD damage and LCD panel utilizing the same

ABSTRACT

A mechanism for preventing ESD damage and LCD panel utilizing the same. The mechanism for preventing ESD damage is configured to make ESD protection devices. The provided ESD protection devices corresponding to the longest fan-out signal lines of an integrated circuit have longer equivalent channel widths than those of the other ESD protection devices or smaller equivalent impedances than those of the other ESD protection devices, thereby discharging the electrostatic charge efficiently.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to ESD protection, and in particular to a mechanism for preventing ESD damage in an electronic device.

2. Description of the Related Art

FIG. 1 is a schematic diagram of signal lines of a conventional liquid crystal display (LCD) panel. The LCD panel comprises a pixel array 12, a plurality of connection areas 10 and a plurality of fan-out signal lines F₁ to F_(n). Integrated circuits such as a data driver and a scan driver drive the pixel array 12 to display images. As shown in FIG. 1, each connection area 10 has a plurality of pads P₁ to P_(n) arranged sequentially for mounting to the corresponding integrated circuit. The fan-out signal lines F₁ to F_(n) are extend from the pads P₁ to P_(n) respectively. The integrated circuits can provide driving signals, such as scan signals and data signals, to the pixel array 12 through the fan-out signal lines F₁ to F_(n). Also, the integrated circuits can receive external signals through the fan-out signal lines F₁ to F_(n).

A thin film transistor (TFT) LCD panel is handled by several machines and operators during the manufacturing process. When a machine or operator generates and transmits electrostatic discharge (ESD) to the TFT LCD panel, signal lines of the TFT LCD panel are open or short, resulting in reduced yield and damage to internal elements. The resulting TFT LCD panel displays abnormal bright or dark lines. TFT LCD panels typically comprise an ESD protection device to prevent ESD from damaging the TFT LCD panel.

Referring to FIG. 1, a conventional method of protecting an LCD panel provides a plurality of ESD protection devices ES₁ to ED_(n) disposed corresponding to the fan-out signal lines F₁ to F_(n). All the ESD protection devices usually have a virtually equal impedance. When ESD occurs in the TFT LCD panel, the ESD protection device of each signal line disposed on outermost side of the connection area 10 has the longest path. Therefore, the electrostatic charges do not disperse and the effectiveness of the protection offered by the ESD protection device is not maintained.

SUMMARY OF THE INVENTION

Accordingly, an object of the present invention is to provide a mechanism for preventing ESD damage in an electronic device, such as an LCD panel. The ESD protection devices corresponding to the longest fan-out signal lines of an integrated circuit have longer equivalent channel widths than those of the other ESD protection devices or smaller equivalent impedances than those of the other ESD protection devices.

Another object of the invention is to provide a mechanism for preventing ESD damage in an electronic device, such as an LCD panel. The ESD protection devices corresponding to the outermost sides of the connection area have the smallest equivalent impedance and equivalent impedances of the other ESD protection devices gradually increase from the outermost sides of the connection area to the center thereof, thereby discharging the electrostatic charge efficiently.

Another object of the invention is to provide a mechanism for preventing ESD damage in an electronic device, such as an LCD panel. Any ESD protection device corresponding to one fan-out signal line of an integrated circuit has an equivalent impedance different from equivalent impedances of the other ESD protection devices, thereby discharging the electrostatic charge efficiently.

Another object of the invention is to provide an liquid crystal display panel utilizing the above mechanism for preventing ESD damages, thereby preventing the LCD panel from damaged by ESD.

A detailed description is given in the following embodiments with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention can be more fully understood by reading the subsequent detailed description and examples with references made to the accompanying drawings, wherein:

FIG. 1 is a schematic diagram of signal lines of a conventional liquid crystal display (LCD) panel.

FIG. 2 shows an example of an ESD protection device composed by a diode circuit.

FIG. 3 shows layout of the diode circuit in FIG. 2.

FIG. 4 shows an embodiment of a mechanism for preventing ESD damages in the present invention.

FIG. 5 shows another embodiment of a mechanism for preventing ESD damage in the present invention.

DETAILED DESCRIPTION OF THE INVENTION

A diode circuit is always applied to an electronic device to serve as an electrostatic discharge (ESD) protection device. The ESD protection device ES₁ shown in FIG. 2 comprises six diodes D₁ to D₆ configured corresponding to the fan-out signal line F₁ in FIG. 1. Generally, two ESD protection devices ES₁ are respectively configured at two terminals of the pad P₁, but only one is shown in FIG. 2.

The diodes D₁ to D₆ within the ESD protection devices ES₁ usually are typically composed by elements having MOS transistor circuit structures, such as, a MOS transistor whose drain is coupled to its gate. FIG. 3 shows a circuit layout of diodes D₁ to D₆ in FIG. 2. As shown in FIG. 3, channel widths of the diodes D₁ to D₃ are CH1 while channel widths of the diodes D₄ to D₆ are CH2. An equivalent impedance of the ESD protection device ES₁ is determined according to the channel widths CH1 and CH2. That is, when an equivalent width composed of the channel widths CH1 and CH2 increases, the equivalent impedance of the ESD protection device ES₁ decreases.

FIRST EMBODIMENT

FIG. 4 shows an embodiment of a mechanism for preventing ESD damage in the present invention. The mechanism is applied to an electronic device, LCD panel.

The LCD panel comprises a pixel array 12, a plurality of connection areas 10, a plurality of fan-out signal lines F₁ to F_(n), and a plurality of ESD protection devices ES₁ to ED_(n). Each connection area 10 has a plurality of pads P₁ to P_(n) arranged sequentially for mounting to one integrated circuit. The pads P₁ to P_(n) are disposed on two outermost sides of the connection area 10. The fan-out signal lines F₁ to F_(n) extend from the pads P₁ to P_(n) respectively. The ESD protection devices ES₁ to ED_(n) are disposed corresponding to the fan-out signal lines F₁ to F_(n). In addition, each ESD protection device comprises a least one element having a MOS transistor circuit structure, such as a MOS transistor whose drain is coupled to its gate.

As shown in FIG. 4, equivalent impedances of the ESD protection devices ES₁ and ED_(n) are designed to be smaller than equivalent impedances of ESD protection devices ES₂ and ED_(n−1). That is, an equivalent channel width L₁ of the ESD protection devices ES₁ and ED_(n) is designed to be longer than an equivalent channel width L₂ of ESD protection devices ES₂ and ED_(n−1).

According to the embodiment, in one connection area 10, the equivalent impedances of the ESD protection devices ES₁ and ED_(n) are small, that is the equivalent channel width L₁ of the ESD protection devices ES₁ and ED_(n) is longest. Therefore, accumulated electrostatic charges on the longest fan-out signal lines F₁ and F_(n) which do not easily disperse charges could be effectively dispersed through the ESD protection devices ES₁ and ED_(n), preventing the LCD panel from ESD damage.

SECOND EMBODIMENT

FIG. 5 shows another embodiment of a mechanism for preventing ESD damages in the present invention. The mechanism is applied to an electronic device, an LCD panel.

The LCD panel comprises a pixel array 12, a plurality of connection areas 10, a plurality of fan-out signal lines F₁ to F_(n), and a plurality of ESD protection devices ES₁ to ED_(n). Each connection area 10 has a plurality of pads P₁ to P_(n) arranged sequentially for mounting to one integrated circuit. The pads P₁ to P_(n) are disposed on two outermost sides of the connection area 10. The fan-out signal lines F₁ to F_(n) extend from the pads P₁ to P_(n) respectively. The ESD protection devices ES₁ to ED_(n) are disposed corresponding to the fan-out signal lines F₁ to F_(n). In addition, each ESD protection device comprises a least one element having a MOS transistor circuit structure, such as a MOS transistor whose drain is coupled to its gate.

As shown in FIG. 5, in one connection area 10, equivalent impedances of the ESD protection devices ES₁ to ED_(n) gradually increase from the ESD protection devices ES₁ and ED_(n) to the center of the connection area 10. That is, equivalent channel widths of the ESD protection devices ES₁ to ED_(j) gradually decrease and equivalent channel widths of the ESD protection devices ES_(j+1) to ED_(n) sequentially increase gradually.

According to the gradual decrease in the lengths of the fan-out signal lines from the two outermost sides of the connection area 10 to the center thereof, the equivalent impedances of the ESD protection devices are designed to gradually increase. That is, the equivalent channel widths of the ESD protection devices gradually decrease from the two outermost sides of the connection area 10 to the center thereof. Therefore, electrostatic charges could be effectively dispersed through the ESD protection devices ES₁ and ED_(n), preventing the LCD panel from ESD damaged.

THIRD EMBODIMENT

The embodiment is a mechanism for preventing ESD damages of the present invention applied to an electronic device. Among all ESD protection devices ES₁ and ED_(n), an equivalent impedance of one ESD protection device ES_(k) (1≦k≦n) is different from these of the others. Each ESD protection device comprises at last one element having a MOS transistor circuit structure. Therefore, an equivalent channel width of the ESD protection device ES_(k) is different these of other protection devices.

While the invention has been described by way of example and in terms of the preferred embodiments, it is to be understood that the invention is not limited to the disclosed embodiments. To the contrary, it is intended to cover various modifications and similar arrangements (as would be apparent to those skilled in the art). Therefore, the scope of the appended claims should be accorded the broadest interpretation so as to encompass all such modifications and similar arrangements. 

1. A mechanism for preventing ESD damage to a electronic device comprising at least one connection area having a plurality of pads (P₁ to P_(n)) arranged sequentially for mounting to an integrated circuit, and a plurality of fan-out signal lines (F₁ to F_(n)) extending from the pads (P₁ to P_(n)) respectively, the pads P₁ and P_(n) disposed on outermost sides of the connection area, the mechanism comprising: a plurality of ESD protection device (ES₁ to ES_(n)) configured corresponding to the fan-out signal lines (F₁ to F_(n)); wherein, equivalent impedances of the ESD protection devices ES₁ and ES_(n) are smaller than equivalent impedances of the other ESD protection devices ES₂ to ES_(n−1).
 2. The mechanism as claimed in claim 1, wherein each ESD protection device comprises at least one element having a MOS transistor circuit structure and equivalent channel widths of the ESD protection devices ES₁ and ES_(n) are longer than equivalent channel widths of the other ESD protection devices ES₂ to ES_(n−1).
 3. A mechanism for preventing ESD damage to a electronic device comprising at least one connection area having a plurality of pads (P₁ to P_(n)) arranged sequentially for mounting to an integrated circuit, and a plurality of fan-out signal lines (F₁ to F_(n)) extending from the pads (P₁ to P_(n)) respectively, the pads P₁ and P_(n) disposed on outermost sides of the connection area, the mechanism comprising: a plurality of ESD protection device (ES₁ to ES_(n)) configured corresponding to the fan-out signal lines (F₁ to F_(n)); wherein, equivalent impedances of the ESD protection devices ES₁ to ES_(j) gradually increase and equivalent impedances of the ESD protection devices ES_(j+1) to ES_(n) gradually decrease, 1<j<n.
 4. The mechanism as claimed in claim 3, wherein each ESD protection device comprises at least one element having a MOS transistor circuit structure, equivalent channel widths of the ESD protection devices ES₁ to ES_(j) gradually decrease, and equivalent channel widths of the ESD protection devices ES_(j+1) to ES_(n) gradually increase.
 5. A mechanism for preventing ESD damage to a electronic device comprising at least one connection area having a plurality of pads (P₁ to P_(n)) arranged sequentially for mounting to an integrated circuit, and a plurality of fan-out signal lines (F₁ to F_(n)) extending from the pads (P₁ to P_(n)) respectively, the pads P₁ and P_(n) disposed on outermost sides of the connection area, the mechanism comprising: a plurality of ESD protection device (ES₁ to ES_(n)) configured corresponding to the fan-out signal lines (F₁ to F_(n)); wherein, an equivalent impedance of one ESD protection device ES_(k) is different from equivalent impedances of the other ESD protection devices, 1≦k≦n.
 6. The mechanism as claimed in claim 5, wherein each ESD protection device comprises at least one element having a MOS transistor circuit structure and an equivalent channel width of the ESD protection device ES_(k) is different from equivalent channel widths of the other ESD protection devices.
 7. A liquid crystal display panel, comprising: a pixel array; at least one connection area having a plurality of pads (P₁ to P_(n)) arranged sequentially for mounting to an integrated circuit, wherein the pads P₁ and P_(n) are disposed on outermost sides of the connection area; a plurality of fan-out signal lines (F₁ to F_(n)) extending from the pads (P₁ to P_(n)) respectively; and a plurality of ESD protection devices (ES₁ to ES_(n)) configured corresponding to the fan-out signal lines (F₁ to F_(n)); wherein, equivalent impedances of the ESD protection devices ES₁ and ES_(n) are smaller than equivalent impedances of the other ESD protection devices ES₂ to ES_(n−1).
 8. The liquid crystal display panel as claimed in claim 7, wherein each ESD protection device comprises at least one element having a MOS transistor circuit structure and equivalent channel widths of the ESD protection devices ES₁ and ES_(n) are longer than equivalent channel widths of the other ESD protection devices ES₂ to ES_(n−1).
 9. The liquid crystal display panel as claimed in claim 8, wherein the equivalent channel widths of the ESD protection devices ES₁ to ES_(j) gradually decrease, and the equivalent channel widths of the ESD protection devices ES_(j+1) to ES_(n) gradually increase, 1<j<n.
 10. A liquid crystal display panel, comprising: a pixel array; at least one connection area having a plurality of pads (P₁ to P_(n)) arranged sequentially for mounting to an integrated circuit, wherein the pads P₁ and P_(n) are disposed on outermost sides of the connection area; a plurality of fan-out signal lines (F₁ to F_(n)) extending from the pads (P₁ to P_(n)) respectively; and a plurality of ESD protection device (ES₁ to ES_(n)) configured corresponding to the fan-out signal lines (F₁ to F_(n)); wherein, an equivalent impedance of one ESD protection device ES_(k) is different from equivalent impedances of the other ESD protection devices, 1≦k≦n.
 11. The liquid crystal display panel as claimed in claim 10, wherein each ESD protection device comprises at least one element having a MOS transistor circuit structure and an equivalent channel width of the ESD protection device ES_(k) is different from equivalent channel widths of the other ESD protection devices. 